TY - JOUR
T1 - Understanding the effect resonant magnetic perturbations have on ELMs
AU - Kirk, A.
AU - Chapman, I.T.
AU - Evans, T.E.
AU - Ham, C.
AU - Harrison, J.R.
AU - Huijsmans, G.
AU - Liang, Y.
AU - Liu, Y.Q.
AU - Loarte, A.
AU - Suttrop, W.
AU - Thornton, A.J.
PY - 2013/12/1
Y1 - 2013/12/1
N2 - All current estimations of the energy released by type I edge-localized
modes (ELMs) indicate that, in order to ensure an adequate lifetime of
the divertor targets on ITER, a mechanism is required to decrease the
amount of energy released by an ELM, or to eliminate ELMs altogether.
One such amelioration mechanism relies on perturbing the magnetic field
in the edge plasma region, either leading to more frequent, smaller ELMs
(ELM mitigation) or ELM suppression. This technique of resonant magnetic
perturbations (RMPs) has been employed to suppress type I ELMs at high
collisionality/density on DIII-D, ASDEX Upgrade, KSTAR and JET and at
low collisionality on DIII-D. At ITER-like collisionality the RMPs
enhance the transport of particles or energy and keep the edge pressure
gradient below the 2D linear ideal magnetohydrodynamic critical value
that would trigger an ELM, whereas at high collisionality/density the
type I ELMs are replaced by small type II ELMs. Although ELM suppression
only occurs within limited operational ranges, ELM mitigation is much
more easily achieved. The exact parameters that determine the onset of
ELM suppression are unknown but in all cases the magnetic perturbations
produce 3D distortions to the plasma and enhanced particle transport.
The incorporation of these 3D effects in codes will be essential in
order to make quantitative predictions for future devices.
AB - All current estimations of the energy released by type I edge-localized
modes (ELMs) indicate that, in order to ensure an adequate lifetime of
the divertor targets on ITER, a mechanism is required to decrease the
amount of energy released by an ELM, or to eliminate ELMs altogether.
One such amelioration mechanism relies on perturbing the magnetic field
in the edge plasma region, either leading to more frequent, smaller ELMs
(ELM mitigation) or ELM suppression. This technique of resonant magnetic
perturbations (RMPs) has been employed to suppress type I ELMs at high
collisionality/density on DIII-D, ASDEX Upgrade, KSTAR and JET and at
low collisionality on DIII-D. At ITER-like collisionality the RMPs
enhance the transport of particles or energy and keep the edge pressure
gradient below the 2D linear ideal magnetohydrodynamic critical value
that would trigger an ELM, whereas at high collisionality/density the
type I ELMs are replaced by small type II ELMs. Although ELM suppression
only occurs within limited operational ranges, ELM mitigation is much
more easily achieved. The exact parameters that determine the onset of
ELM suppression are unknown but in all cases the magnetic perturbations
produce 3D distortions to the plasma and enhanced particle transport.
The incorporation of these 3D effects in codes will be essential in
order to make quantitative predictions for future devices.
U2 - 10.1088/0741-3335/55/12/124003
DO - 10.1088/0741-3335/55/12/124003
M3 - Article
SN - 0741-3335
VL - 55
SP - 124003
JO - Plasma Physics and Controlled Fusion
JF - Plasma Physics and Controlled Fusion
IS - 12
ER -